Simulating Time Evolution with Fully Optimized Single-Qubit Gates

We propose a novel method to sequentially optimize arbitrary single-qubit gates in parameterized quantum circuits for simulating real and imaginary time evolution. Unlike previously-known methods, the proposed method fully utilizes all parameters of single-qubit gates and therefore can potentially obtain better performance. Specifically, the proposed method simultaneously optimizes both the axis and the angle of a single-qubit gate, while the known methods either optimize the angle with the axis fixed, or vice versa. The proposed method is shown to generalize the known methods and results in a sinusoidal cost function parameterized by the axis and angle of rotation. Furthermore, we demonstrate how the proposed method can be extended to optimize a set of parameterized two-qubit gates with excitation-conservation constraints, which includes the Hop and the Reconfigurable Beam Splitter gates. We perform numerical experiments showing the power of the proposed method to find ground states of typical Hamiltonians with quantum imaginary time evolution using parameterized quantum circuits.